RhoJ Regulates α5β1 Integrin Trafficking to Control Fibronectin Remodeling during Angiogenesis

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Direct measurement of islet amyloid polypeptide fibrillogenesis by mass spectrometry

A novel method for monitoring fibrillogenesis is developed and applied to the amyloidogenic peptide, islet amyloid polypeptide (IAPP). The approach, based on electrospray ionization mass spectrometry, is complementary to existing assays of fibril formation as it monitors directly the population of precursor rather than product molecules. We are able to monitor fiber formation in two modes: a quenched mode in which fibril formation is halted by dilution into denaturant and a real time mode in which fibril formation is conducted within the capillary of the electrospray source. Central to the method is the observation that fibrillar IAPP does not compromise the ionization of monomeric IAPP. Furthermore, under mild ionization conditions, fibrillar IAPP does not dissociate and contribute to the monomeric signal. Critically, we introduce an internal standard, rat IAPP, for analysis on the mass spectrometer. This standard is sufficiently similar in sequence in that it ionizes identically to human IAPP. Furthermore, the sequence is sufficiently different in that it does not form fibrils and is distinguishable on the basis of mass. Applied to IAPP fibrillogenesis, our technique reveals that precursor consumption in seeded reactions obeys first-order kinetics. Furthermore, a consistent level of monomer persists in both seeded and unseeded experiments after the fibril formation is complete. Given the inherent stability of fibrils, we expect this approach to be applicable to other amyloid systems.     

Flanking domain stability modulates the aggregation kinetics of a polyglutamine disease protein

Spinocerebellar Ataxia Type 3 (SCA3) is one of nine polyglutamine (polyQ) diseases that are all characterized by progressive neuronal dysfunction and the presence of neuronal inclusions containing aggregated polyQ protein, suggesting that protein misfolding is a key part of this disease. Ataxin-3, the causative protein of SCA3, contains a globular, structured N-terminal domain (the Josephin domain) and a flexible polyQ-containing C-terminal tail, the repeat-length of which modulates pathogenicity. It has been suggested that the fibrillogenesis pathway of ataxin-3 begins with a non-polyQ-dependent step mediated by Josephin domain interactions, followed by a polyQ-dependent step. To test the involvement of the Josephin domain in ataxin-3 fibrillogenesis, we have created both pathogenic and nonpathogenic length ataxin-3 variants with a stabilized Josephin domain, and have both stabilized and destabilized the isolated Josephin domain. We show that changing the thermodynamic stability of the Josephin domain modulates ataxin-3 fibrillogenesis. These data support the hypothesis that the first stage of ataxin-3 fibrillogenesis is caused by interactions involving the non-polyQ containing Josephin domain and that the thermodynamic stability of this domain is linked to the aggregation propensity of ataxin-3.     

Detecting bioactive amyloid beta peptide species in Alzheimer's disease

Amyloid beta peptide (A beta) is believed to play a central role in the pathogenesis of Alzheimer's disease (AD). However, the form of A beta that induces neurodegeneration in AD, defined here as bioactive A beta, is not clear. Preventing the formation of bioactive A beta or inactivating previously formed bioactive A beta should be a promising approach to treat AD. We have previously developed a cell-based assay for the detection of bioactive A beta species. The assay is based upon the correlation between the ability of an A beta sample to induce a unique form of cellular MTT [3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide] formazan exocytosis, and its ability to activate glia and induce neurotoxicity. Here, we show that this cell-based assay is not only useful for a cellular model of A beta amyloidogenesis but is also able to detect bioactive A beta species in a transgenic mouse model of AD, as well as in post-mortem cortex samples from AD patients. There is a good correlation between the extent of glia activation and the level of bioactive A beta species in the mouse brain. A promising deuteroporphyrin that can inactivate bioactive A beta species was also identified using this assay. These novel insights and findings should have important implications for the treatment of AD.     

Purification and partial characterization of a type V like collagen from the muscle of marine prawn,Penaeus indicus

The muscle collagen of marine prawn,Penaeus indicus, was isolated by limited pepsin digestion. Based on selective salt precipitation, amino acid composition and gel electrophoretic pattern, the major collagen was found to be a homotrimer of á 1 chain, similar to type V collagen of vertebrates. Electron microscopy of reconstituted fibrils, made for the first time from a crustacean species, revealed a characteristic 64 nm periodicity. Biochemical studies indicate a less than normal amount of associated carbohydrates and an increased alanine content The major collagen had a denatu ration temperature of 37°C with an intrinsic viscosity of 11.3 dl/g. Spectral characteristics of the major collagen were studied. Results suggest the presence of genetically distinct collagen types and acid resistant cross links in crustacean muscle.     

Morphological characterization of tendon development during chick embryogenesis: measurement of birefringence retardation

Morphological observations and physical measurement of (I) birefringence retardation, (2) mean fibre profile width, and (3) cell volume fraction were used to characterize chick hind limb extensor tendon development. Observations were made at days 7, 10, 14 and 17 embryologic and 1-1.5 post-hatching. Microanatomical observations illustrated a sequential development of tendon microanatomy consisting of (1) a uniaxial cellular framework with discontinuous collagen fibril bundles present in day 7 embryos; (2) a continuous network of birefringent collagen fibres, and early evidence of tendon fasciculation and crimp development by embryonic day 10; and (3) completion of the basic cytoarchitecture of tendon observed at day 14 of embryogenesis. These observations suggest that collagen deposition in tendon involves first a longitudinal and then a lateral organization of tendon fibroblasts. Associated with the progressive anatomical development of tendon was an increase in birefringence retardation, mean collagen fibre profile width, and a decrease in the cell volume fraction. Birefringence retardation per unit thickness, however, did not change. This suggested that the fibril packing density of the fibres remained constant, although the fibres were observed to increase in size. These results indicate that collagen fibrillogenesis in vivo can be quantitatively studied by measurement of the birefringence retardation using polarized light.     

Establishment of Constraints on Amyloid Formation Imposed by Steric Exclusion of Globular Domains

In many disease-related and functional amyloids, the amyloid-forming regions of proteins are flanked by globular domains. When located in close vicinity of the amyloid regions along the chain, the globular domains can prevent the formation of amyloids because of the steric repulsion. Experimental tests of this effect are few in number and non-systematic, and their interpretation is hampered by polymorphism of amyloid structures. In this situation, modeling approaches that use such a clear-cut criterion as the steric tension can give us highly trustworthy results. In this work, we evaluated this steric effect by using molecular modeling and dynamics. As an example, we tested hybrid proteins containing an amyloid-forming fragment of Aβ peptide (17–42) linked to one or two globular domains of GFP. Searching for the shortest possible linker, we constructed models with pseudo-helical arrangements of the densely packed GFPs around the Aβ amyloid core. The molecular modeling showed that linkers of 7 and more residues allow fibrillogenesis of the Aβ-peptide flanked by GFP on one side and 18 and more residues when Aβ-peptide is flanked by GFPs on both sides. Furthermore, we were able to establish a more general relationship between the size of the globular domains and the length of the linkers by using analytical expressions and rigid body simulations. Our results will find use in planning and interpretation of experiments, improvement of the prediction of amyloidogenic regions in proteins, and design of new functional amyloids carrying globular domains.     

Collagen fibrillogenesis in tendon development: current models and regulation of fibril assembly

Tendons are collagen-based fibrous tissues that connect and transmit forces from muscle to bone. These tissues, which are high in collagen type I content, have been studied extensively to understand collagen fibrillogenesis. Although the mechanisms have not been fully elucidated, our understanding has continued to progress. Here, we review two prevailing models of collagen fibrillogenesis and discuss the regulation of the process by candidate cellular and extracellular matrix molecules. Although numerous molecules have been implicated in the regulation of collagen fibrillogenesis, we focus on those that have been suggested to be particularly relevant to collagen type I fibril formation during tendon development, including members of the collagen and small leucine-rich proteoglycan families, as well as other molecules, including scleraxis, cartilage oligomeric matrix protein, and cytoskeletal proteins.     

Influence of the germline sequence on the thermodynamic stability and fibrillogenicity of human lambda 6 light chains

Light chain-associated amyloidosis is a fatal disease characterized by the aggregation and pathologic deposition of monoclonal light chain-related fragments as amyloid fibrils in organs or tissues throughout the body. Notably, it has been observed that proteins encoded by the lambda variable light chain (V(L)) gene segment 6a are invariably associated with amyloid deposition; however, the contribution of the gene to this phenomenon has not been established. In this regard, we have determined the thermodynamic stability and kinetics of in vitro fibrillogenesis of a recombinant (r) V(L) protein, designated 6aJL2, which contains the predicted sequences encoded by the 6a and JL2 germline genes. Additionally, we studied a 6a mutant (6aJL2-Arg25Gly), that is present in approximately 25% of all amyloid-associated lambda6 light chains. Remarkably, the wild-type 6aJL2 protein was more stable than were all known amyloidogenic kappa and lambda light chains for which stability parameters are available; more importantly, it was even more so (and less fibrillogenic) than the only clinically proven nonamyloidogenic lambda6 protein, Jto. Conversely, the mutated 6aJL2-R25G molecule was considerably less stable and more fibrillogenic than was the native 6aJL2. Our data indicate that the propensity of lambda6 light chains to form amyloid can not be attributed to thermodynamic instability of the germline-encoded Vlambda6 domain, but rather, is dependent on sequence alterations that render such proteins amyloidogenic.     

Morphologies of Fibronectin Fibrils Formed under Shear Conditions and Their Cellular Adhesiveness Properties

Fibrillar fibronectin (FFN) is a biological active form of FN which form linear and branched meshwork around cells and support cellular activities. Previous studies have demonstrated that shear stress can induce cell-free FN fibrillogenesis. In this study, we further examined the effect of shear stress conditions on morphology of formed FFN and preliminarily looked for relationship between FFN’s morphology and cell adhesion. Plasma FN at 50 µg/ml was perfused through channel slides at shear rates of 500 s^-1 or 4000 s^-1. Our results showed that there were four FFN structures formed: (1) FN nodules, (2) fibril in different sizes (3) with or without nodule attachment, and (4) fibrillar matrix. At 4000 s^-1, FFN fibrils was formed within the first 10 min and reached the highest surface coverage only after 20 min. In contrast, FFN formation was significant more slowly at 500 s^-1 at which only FN nodules and small fibrils were formed. Platelets bound on thin layer of FN and rarely found on large FN fibrils. In contrast, fibroblast stretched their shape on platform of FFN matrix and bound actively to all types of FFNs. Taken together, our data suggests a morphological dependent biological activity of FFN.